DE60034759T2 - System and method for transmission power control - Google Patents

Description

The The present invention relates to a cellular or mobile communication system and in particular, a transmission power control technique in a base station.

In CDMA (Code Division Multiple Access) systems is a soft or Soft handover a known technique according to which a mobile station at the same time communicates with multiple base stations to get a smooth (hitless) To enable circuit switching by connecting to a new base station, while a connection to an old base station is maintained. Through soft handover becomes a diversity provided, i. a method in which independent fading signals are used be over several transmission paths receive and all transmit the same message or message, for reliability the transmission to improve.

However, in the case of a downlink soft handover (from a base station to a mobile station), multiple base stations simultaneously transmit radio signals to the mobile station, causing substantial interference in neighboring cells. As a technique for suppressing an increase in interference in the case of a downlink soft handover, Furukawa (Technical Report of Institute of Electronics, Information and Communication Engineers, RCS91-218, February 1998, page 40, Second Chapter) has a downlink transmission power control method been proposed. An overview of this downlink transmission power control method will be described below with reference to FIGS 1 - 4 described.

It It is assumed that a mobile station for a soft handover with multiple Base stations communicates.

According to 1 a downlink signal is received from each of the base stations at an antenna and via a duplexer 101 to a down-converter 102 transfer. The down converter 102 converts the received radio frequency (RF) signal into a baseband signal and provides it to a pilot signal receiver 103 out. The pilot signal receiver 103 detects a pilot signal from the received baseband signal and measures its intensity or quality. A section 104 for determining a primary base station compares the intensity / quality measurements of the received signals to determine a base station transmitting a maximum intensity / quality signal as the primary base station with which communication is to be performed. A base station selection signal generator 105 generates a base station selection signal from the primary base station identification number. A control signal generator 106 generates control signals having a transmission power control signal, and outputs the control signals together with that from the base station selection signal generator 105 received base station selection signal to a combiner 107 out. The combiner 107 combines the control signal and the base station selection signal with an uplink information signal to generate a transmission signal. The transmission signal is through a boost converter 108 converted into an RF transmission signal. The RF transmission signal is through an RF amplifier 109 further amplified and then as an uplink signal through the duplexer 101 transmitted to the base stations. Each of the base stations communicating with the mobile station receives the uplink signal containing the base station selection from the mobile station.

According to 2 For example, the uplink signal at each of the base stations connected to the mobile station is received at an antenna and via a duplexer 201 to a down-converter 202 transfer. The down converter 202 converts the received RF uplink signal into a baseband signal and applies it both to a transmit power control signal demodulator 203 as well as to a base station selection signal demodulator 204 out. The transmission power control signal demodulator 203 demodulates the transmit power control signal from the received baseband signal and provides it to a transmit power controller 205 out. The base station selection signal demodulator 204 demodulates the baseband select signal from the received baseband signal and provides it to a controller 206 for a primary / non-primary base station mode.

The transmit power controller 205 generates a transmission power control intermediate value P1 in response to the transmission power control signal demodulator 203 supplied transmission power control signal and outputs the transmission power control intermediate value P1 to the controller 206 for a primary / non-primary base station mode.

The controller 206 for a primary / non-primary base station mode updates the transmission power control intermediate value P1 in response to the base station selection signal to generate a transmission power control end value P2 and to a transmission controller 207 issue. The details of the controller 206 for a primary / non-primary base station mode will be described later.

The transmission controller 207 receives a downlink transmission signal and performs output control such that the transmission power of the downlink transmission signal is responsive to the transmission power control end value P2 is set. The power down-regulated transmit signal is provided by a boost converter 208 converted into a high frequency (HF) downlink signal. The RF downlink transmit signal is passed through the RF amplifier 209 amplified and then over the duplexer 201 transmitted to the mobile station.

According to 3A A transmission signal between the mobile station and a plurality of base stations has a frame structure. A frame D-001 consists of Fn slots assigned successive numbers from 0 to Fn-1.

As described above, the mobile station transmits the base station selection signal for soft handover to the base stations with which it is communicating. The base station selection signal consists of a sequence of bits identifying the individual base stations. Because multiple bits are used to form a base station select signal, redundancy can be provided, thereby reducing transmission errors caused by noise and / or fading. Hereinafter, a series of 8 bits identifying the individual base stations will be referred to as "base station selection code word". An example will be given below with reference to FIG 3B described.

As in 3B 2, assuming that a base station selection code word E-002 is represented by "00001111", the respective sections of the code word E-002 are assigned to the dedicated fields E-001 of each other up-link slot E-003. That is, the base station selection code word E-002 is divided into 8 sections (each section corresponding to one bit), and the 8 sections are transmitted through the dedicated slots E-001 of various slots E-003. Here, one period of a base station selection control signal E-004 is 8 slots each having a dedicated field E-001 for storing a corresponding bit of the 8-bit base station selection code word E-002. Two or more bits of the base station selection codeword E-002 may be included in a slot. The larger the number of bits received, the shorter the period of the base station selection control signal E-004.

in the Cellular systems measure every base station and every mobile station intensities of pilot signals and interference signals from neighboring cells be received, at regular intervals, around her for a handover control and a connection control (Call Admission Control) to use. When a base station is measuring for pilot signals and performs interference signals, becomes the uplink transmission each of the mobile stations connected to the base station temporarily interrupted to a precise To allow measurement of signals from neighboring cells. Furthermore occur cases on where the uplink transmission a mobile station during Communication is interrupted to cause uplink interference in the network Case of a packet transfer and a non-voice transmission suppress.

conventional Base station (BS) Update Mode

As described above, each controller updates 206 for a primary / non-primary base station mode in each of the base stations, the transmission power control intermediate value P1 in response to the base station selection code word E-002 to generate a transmission power control final value P2. The conventional base station mode control becomes as in 4 shown executed.

According to 4 the controller receives 206 for a primary / non-primary base station mode, the base station selection code word E-2002 from the base station selection signal demodulator 204 (Step 401 and detects the base station identification number BS_ID _RSV from the base station selection code word E-002 (step S402). Then, it determines whether the base station identification number BS_ID _{RSV is} identical with the identification number ID of its own base station (step S403). If the base station identification number BS_ID _{RSV is} identical to the identification number ID of the own base station (YES in step S403), the transmission power control end value P2 becomes that of the transmission power controller 205 supplied transmission power control intermediate value P1 set, ie P2 = P1 (primary base station mode) (step S404). If the base station identification number BS_ID _{RSV is} not identical to the own base station identification number ID (NO in step S403), the transmission power control end value P2 is set to a predetermined minimum transmission power control value P _MIN , ie P2 = P _MIN (non-primary base station mode) (step S405). The predetermined minimum transmission power control value P _MIN may be zero. The transmission power control end value P2 is sent to the transmission controller 207 outputted (step S406).

In this way, the transmission power at each of the base stations communicating with the mobile station is selectively turned on and off in response to the base station selection code word E-002 received from the mobile station. This prevents multiple base stations from simultaneously transmitting the same signal to a single mobile station, thereby suppressing interference to neighboring cells and improved communication quality of production.

1) loss of the base station selection signal

However, if the uplink transmission of each of the mobile stations connected to the base station is temporarily interrupted, as described above, the base station selection code word E-002 to be transmitted to the base stations will become partially or completely vacant, as in FIG 3C is shown.

that is, if the uplink transmission the mobile station for an uplink transmission gap period F-001 in the base station control period E-004 is interrupted the base station selection code word E-002 partially incomplete, so that an incomplete code word F-002 is received at the base stations. Such a partial or complete loss of the base station selection codeword E-002 leads to a substantially reduced reliability of the base station selection control.

2) change the base station update timing

As described above while the soft handover process several base stations the same signal to a single mobile station. In this case, the transmission time becomes of the signal adjusted so that the transmitted by the base stations Signals within a permissible Time deviation arrive at the mobile station. Because the transmission links from the mobile station to the base stations from base station to base station are different, the respective transmission times of the base stations different. On the other hand, the base stations also receive the uplink signal from the mobile station due to the different transmission links at different times.

If the respective transmission times of the downlink signals and the reception times of the uplink signal containing the base station selection signal to the Base stations are different, as described above, occur cases in which the actual Base station mode update times of Base Station Base Station to base station are different. Details are described below.

According to 5 is a time slot denoted by reference G-001, and each transmission signal has a frame structure in which 15 slots are numbered 0-14. For the sake of convenience, it is assumed that two base stations 1 and 2 transmit downlink transmission signals G-002 and G-003 at respective transmission times (durations D1 and D2) to the mobile station set such that the downlink transmission signals arrive within an allowable time deviation arrive the mobile station.

Therefore receives the mobile station transmits the downlink transmission signals G-002 as a downlink receive signal G-004 from the base station 1 and receives approximately simultaneously the downlink transmission signals G-003 as a downlink reception signal G-005 from the base station 2.

The mobile station transmits an uplink transmission signal G-006 to the base stations 1 and 2 with a transmission time offset T _TR with respect to the reception of the downlink reception signals G-004 and G-005. As described above, the uplink transmission signal G-006 has the base station selection code word, so that respective sections of the base station code word are included in the base station code word 3B transmitted dedicated fields are transmitted.

The Base station 2 receives uplink receive signal G-006 as an uplink receive signal G-007 a signal delay D3, and the base station 1 receives the Uplink transmit signal G-006 as an uplink receive signal G-008 with a signal delay D4.

It is assumed that a complete base station selection codeword is received when slot No. 14 has been received. In this case, the base station 2 starts with the in 4 illustrated update processing for the primary / non-primary base station mode when the last part of the base station selection code word is stored in the dedicated field G-020 in the slot No. 14 of the uplink received signal G-007. As in 5 is shown, the reception time of the last section of the base station selection code word falls in the subsequent slot No. 0. Therefore, the actual update of the primary / non-primary mode is performed in the subsequent slot G-017 No. 1.

Similarly, the base station 1 starts with the in 4 illustrated update processing for the primary / non-primary base station mode, when the last portion of the base station selection code word is stored in the dedicated field G-021 in the slot No. 14 of the uplink received signal G-008. As in 5 1, the reception time of the last section of the base station selection codeword falls within the next-but-one slot, that is, the slot No. 1. Therefore, the actual update of the primary / non-primary mode is carried out in the next slot No. 2 above.

In this way, from the viewpoint of the mobile station, the update timing for the pri Because the base station selection code word is transmitted during the time of the base station selection control, changes in the base station mode update time may downlink Signal loss. To avoid such signal loss, the mobile station requires additional circuitry to constantly monitor the base station mode update time.

In the EP-A-0936751 a base station transmission power control during a soft handover is described. The transmission power control is performed according to a command from the mobile station only in the base station serving as a primary base station having a minimum propagation loss with respect to the mobile station during the soft handover.

It An object of the present invention is a transmission power control method and system for enabling a stable and reliable signal transmission provide.

It Another object of the present invention is an updating method for one primary Base station mode, through which a stable and reliable operation in the case of base station selection signal loss.

It Yet another object of the present invention is an updating method for one primary Base station mode through which a synchronization between mode update times of mobile station communicating Base stations enabled becomes.

These Tasks are solved by the features of the claims.

According to the invention, as described above, when the loss value is one of a base station selection signal received by a mobile station exceeds specified value, by the base station mode, the signal power of the downlink signal is not diminished, regardless of whether the base station itself by the base station selection signal as primary Base station is specified or not. This can be a through a little reliable Base station selection signal generated base station selection error be avoided. In particular, when a base station is called the primary Base station is specified, avoiding the base station the transmission power is incorrectly reduced or switched off.

In addition, because the update times of the base stations at the mobile station received downlink signal synchronized with each other, one caused by a loss of synchronization Downlink signal loss can be avoided without being in the mobile station an additional circuit to monitor the mode update time is required.

1 Fig. 12 is a schematic diagram showing a configuration of a mobile station in a mobile communication system;

2 FIG. 12 is a schematic diagram showing a configuration of a base station in the mobile communication system; FIG.

3A Fig. 10 is a diagram showing a frame format of an uplink signal transmitted from a mobile station to a base station;

3B FIG. 12 is a diagram illustrating the frame format of an uplink signal for explaining a method of transmitting a base station selection signal; FIG.

3C Fig. 16 is a diagram for illustrating the frame format of an uplink signal for explaining an uplink transmission gap period;

4 Fig. 10 is a flowchart showing a conventional method of updating the primary / non-primary base station mode;

5 Fig. 13 is a timing chart showing the base station mode update timing in the conventional method;

6 FIG. 12 is a flow chart illustrating a method of updating the primary / non-primary base station mode according to a first embodiment of the present invention; FIG.

7 FIG. 12 is a flowchart for illustrating a method of updating the primary / non-primary base station mode according to a second embodiment of the present invention; FIG.

8th FIG. 12 is a timing chart showing the base station mode update timing according to the second embodiment; FIG. and

9 FIG. 12 is a flowchart showing a method of updating the primary / non-primary base station mode according to a third embodiment of the present invention.

Hereinafter, the preferred embodiments of the present invention will be described with reference to FIGS 6 - 9 described in detail. Each of the embodiments is used as control processing of the controller provided at the base station 206 described for the primary / non-primary base station mode by a program controlled processor in the controller 206 for the primary / non-primary base station mode running control program is implementable.

As described above, the controller provided in each of the base stations updates 206 for the primary / non-primary base station mode, the transmission power control intermediate value P1 in response to the base station selection code word E-002 to generate a transmission power control end value P2.

First embodiment

According to 6 A first embodiment of the present invention controls the transmission power considering the loss value of a base station selection signal or code word.

In particular, the controller receives 206 for the primary / non-primary base station mode, the base station selection codeword from the base station selection signal demodulator 204 (Step S601) and measures the loss value of the base station selection codeword (Step S602). The loss value of the base station selection codeword may be the number of missing bits according to 3C or the ratio of the number of missing bits to the total number of bits of the base station selection codeword. Hereinafter, the loss value of the base station code word will be denoted by L _CW .

Subsequently, it is determined whether the loss value L _{CW of} the base station selection code word is greater than a threshold value L _TH (step S603). The threshold value L _TH may vary depending on the length of the base station selection codeword.

If L _CW> L _TH (YES at step S603), it is determined that the demodulated base station selection code word is not sufficiently reliable, and the transmission power control final value P2 is set to the transmit power from the controller 205 supplied transmission power control intermediate value P1 set, ie, P2 = P1 (primary base station mode) (step S604). That is, the transmission power is not suppressed regardless of whether the base station itself is the primary base station or not.

If L _{CW is} less than or equal to L _TH (NO in step S603), the base station identification number BS_ID _{RSV is} detected by the base station selection code word (step S605). Subsequently, it is decided whether the base station identification number BS_ID _{RSV is} identical with the own identification number ID (step S606).

If the base station identification number BS_ID _{RSV is} identical to the own identification number ID (YES in step S606), the transmission power control end value P2 is set to the transmission power control intermediate value P1, that is, P2 = P1 (primary base station mode) (step S604). If the base station identification number BS_ID _{RSV is} not identical with the own identification number ID (NO in step S606), the transmission power control end value P2 is set to a predetermined minimum transmission power control value P _MIN , ie, P2 = P _MIN (non-primary base station mode) (step S607 ). The predetermined minimum transmission power control value P _MIN may be zero. The transmission power control end value P2 is sent to the transmission controller 207 outputted (step S608).

Alternatively, if the base station identification number BS_ID _{RSV is} not identical with the own identification number ID (NO in step S606), it may further be decided whether the reception quality of the base station selection code word reaches a predetermined level. When the reception quality does not reach the predetermined level, it is judged that the demodulated base station selection code word is not sufficiently reliable, and the transmission power control end value P2 can be set to the transmission power control intermediate value P1 (step S604).

If, As described above, the loss value of the base station selection code word is larger as the threshold, that is, when the demodulated base station selection code word not sufficiently reliable is, the transmission power is independent of whether the base station even as the primary one Base station is specified or not, not suppressed.

Second embodiment

According to 7 For example, a second embodiment of the present invention controls the base station mode update time such that synchronization between the update times of the primary / non-primary modes can be achieved.

That is, the controller 206 for the primary / non-primary base station mode, the base station selection codeword receives from the base station selection signal demodulator 204 (Step S701) and detects the base station identification number BS_ID _RSV from the base station selection code word E-002 (Step S702). Then a variable i on the Number of a current slot and a variable j are set to the number of a slot which carries the last portion of the base station selection code word (S703). Thereafter, it is decided whether or not the following equation (1) is satisfied (step S704): i = (j + Tos) mod Fn (1) where Tos denotes the wait time required for the mode update, Fn the number of slots contained in a frame, and X mod Y an operator whose result represents the remainder of a division operation (X / Y). That is, the base station mode updating operation is not carried out until the current slot reaches slot # (j + Tos) mod Fn.

If Equation (1) is satisfied (YES in step S704), it is determined whether the base station identification number BS_ID _{RSV is} identical to the own identification number ID (step S705). If the base station identification number BS_ID _{RSV is} identical to the own identification number ID (YES in step S705), the transmission power control end value P2 becomes that of the transmission power controller 205 supplied transmit power control intermediate value P1 sets, ie, P2 = P1 (primary base station mode) (step S706). If the base station identification number BS_ID _{RSV is} not identical with the own identification number ID (NO in step S705), the transmission power control end value P2 is set to a predetermined minimum transmission power control value P _MIN , ie, P2 = P _MIN (non-primary base station mode) (step S707 ). The predetermined minimum transmission power control value P _MIN may be zero. The transmission power control end value P2 is sent to the transmission controller 207 outputted (step S708).

Alternatively, if the base station identification number BS_ID _{RSV is} not identical with the own identification number ID (NO in step S705), it may further be determined whether the reception quality of the base station selection code word reaches a predetermined level. When the reception quality does not reach the predetermined level, it is judged that the demodulated base station selection code word is not sufficiently reliable, and the transmission power control end value P2 can be set to the transmission power control intermediate value P1 (step S706).

In 8th is a time slot indicated by the reference J-001, and each transmission signal has a frame structure in which Fn (= 15) slots are numbered 0-14. For the sake of convenience, it is assumed that two base stations 1 and 2 transmit downlink transmission signals J-002 and J-003 at respective transmission times (signal times D1 and D2) to the mobile station set such that the downlink transmission signals arrive within an allowable time deviation arrive the mobile station.

Therefore receives the mobile station transmits the downlink transmission signals J-002 as a downlink transmission signal J-004 from the base station 1 and approximately simultaneously the downlink transmission signal J-003 as a downlink received signal from the base station 2.

The mobile station transmits an uplink transmission signal J-006 to the base stations 1 and 2 with a transmission time offset T _TR relating to the reception of the downlink reception signals J-004 and J-005. As described above, the uplink transmit signal J-006 has the base station select codeword such that respective portions of the base station codeword are included in the base station codeword 3B transported shown dedicated fields.

The Base station 2 receives the uplink transmission signal J-006 as an uplink reception signal J-007 a signal delay D3, and the base station 1 receives the Uplink transmission signal J-006 as an uplink receive signal J-008 with a signal propagation delay D4.

It It is assumed that a complete base station selection code word is received when the slot No. 14 has been received, i. j = 14, and the mode update wait time Tos is set to 3 is, Fn = 15. In this case, (j + Tos) modFn = 2. Therefore, the Base Station 1 the actual Mosus update in slot J-0017 # 2 off. Similarly, leads the Base Station 1 as well the actual Mode update in slot J-017 # 2 off.

On this way, from the mobile station's point of view, is the update time for the primary base station, i.e. For the base station 1, synchronized with that of the base station 2.

Preferably is the wait Tos as short as possible to a high-speed mode switching operation to achieve. Because the signal transit time and the processing time in a base station change can, can the wait Tos while the communication can be made variable.

In addition, can the waiting time Tos depending on from the number j of the slot in which the last section of the Base station code word is transported, to be changed. In this case can change the update time of the primary base station mode on the Mobile station to a desired Time to be set.

Third embodiment

According to 9 is a third execution Form of the present invention, a combination of the first and the second embodiment. Steps S901-S905 are the same as steps S701-S705 of FIG 7 , If the base station identification number BS_ID _{RSV is} identical to the own identification number ID (YES in step S905), it is decided whether the loss value L _{CW of} the base station selection code word is greater than the threshold value L _TH (step S906).

If L _CW > L _TH (YES in step S906), it is judged that the demodulated base station selection code word is not sufficiently reliable, and the transmission power control end value P2 is set to that of the transmission power controller 205 supplied transmission power control intermediate value P1 set, ie, P2 = P1 (primary base station mode) (step S604). That is, the transmission power is not suppressed regardless of whether the base station itself is the primary base station or not.

If L _{CW is} less than or equal to L _TH (NO in step S906), the transmission power control end value P2 is set to a predetermined minimum transmission power control value P _MIN , ie, P2 = P _MIN (non-primary base station mode) (step S908). The transmission power control end value P2 is sent to the transmission controller 207 outputted (step S909).

Alternatively, if the base station identification number BS_ID _{RSV is} not identical with the own identification number ID (NO in step S905), it may further be decided whether the reception quality of the base station selection code word reaches a predetermined level. When the reception quality does not reach the predetermined level, it is judged that the demodulated base station selection code word is not sufficiently reliable, and the transmission power control end value P2 can be set to the transmission power control intermediate value P1 (step S907).

If, As described above, the loss value of one of Mobile station received base station selection signal due to a gap Uplink transmission the mobile station exceeds a predetermined level becomes the base station mode regardless of whether by the base station selection signal, the base station itself as primary Base station is specified or not, the base station mode on the primary Mode set. This may cause a decision error according to which the Base station due to a receive error on the non-primary base station mode is set to be effectively eliminated, creating a stable and reliable quality a downlink signal transmitted from the base station to the mobile station is obtained.

In addition, because the update times of the base stations at the mobile station received downlink signal synchronized with each other, one caused by a loss of synchronization Downlink signal loss can be avoided without being in the mobile station an additional circuit to monitor the mode update time is required.

Claims (8)

Method for controlling the transmission power of a from a base station to a mobile station transmitted downlink signal dependent on from a base station selection signal, wherein the mobile station is at least a primary one Base station among a plurality of base stations connected to the mobile station for a Soft handover selects, around which the at least one primary To generate base station specifying base station selection signal, with the steps: at each of the base stations: (a) receive the base station selection signal from the mobile station; marked by (b) measuring the height a signal loss of the base station selection signal; (C) Determine if the height the signal loss of the base station selection signal exceeds a threshold; in which (d1) if the height the signal loss of the base station selection signal the threshold does not exceed and the base station selection signal the receiving base station as the primary one Base station specifies the transmission power of the downlink signal is set to a normal level; and (d2) when the amount of signal loss of the base station selection signal does not exceed the threshold and the base station selection signal the receiving base station not as the primary base station specifies the transmission power of the downlink signal to a minimum Level is set; and (e) if the level of signal loss of the Base station selection signal exceeds the threshold, the transmission power of the downlink signal is set to the normal level. The method of claim 1, wherein the amount of signal loss the base station selection signal of a number of erroneously received Bits in the base station selection signal corresponds. The method of claim 1, wherein the amount of signal loss of the base station selection signal is a ratio between an interrupted one Length to Length of the Base station selection signal corresponds. The method of claim 1, 2 or 3, wherein the threshold in dependence of the length of the base station selection signal changes. Device for controlling the transmission power of a downlink signal dependent on from a base station selection signal in each base station of a mobile communication system, wherein a mobile station comprises at least one primary base station among a plurality Base stations connected to the mobile station for a soft handover selects around which the at least one primary To generate base station specifying base station selection signal, With: (a) a recipient for receiving the base station selection signal from the mobile station; marked by (b) a controller for controlling the transmission power of the transmitted to the mobile station Downlink signal through (c) measuring the amount of signal loss of the Base station selection signal; (d) Determine if the amount of signal loss the base station selection signal exceeds a threshold; in which (e1) if the height the signal loss of the base station selection signal the threshold does not exceed and the base station selection signal the receiving base station as the primary one Base station specifies the transmission power of the downlink signal is set to a normal level; and (e2) when the amount of signal loss of the base station selection signal does not exceed the threshold and the base station selection signal the receiving base station not as the primary base station specifies the transmission power of the downlink signal to a minimum Level is set; and (f) if the amount of signal loss of the Base station selection signal exceeds the threshold, the transmission power of the downlink signal is set to the normal level. Apparatus according to claim 5, wherein the level of signal loss the base station selection signal of a number of erroneously received Bits in the base station selection signal corresponds. Apparatus according to claim 5, wherein the level of signal loss of the base station selection signal is a ratio between an interrupted one Length to Length of the Base station selection signal corresponds. Apparatus according to claim 5, 6 or 7, wherein the Threshold depending on of the length of the base station selection signal changes.